A rotor-side lead block integrally holds a plurality of external connection terminals electrically and directly connected to a connection land of a first sub FPC. The first sub FPC is housed and fixed in the rotor-side connector portion. The external connection terminals and the connection land of the first sub FPC are connected to each other via solder. The first holding member holds the connection land of the first sub FPC between the rotor-side lead block and the first holding member.
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7. A rotary connector comprising:
a stator;
a rotor rotatable relative to the stator;
a flexible printed circuit board housed between the stator and the rotor and connected at both ends thereof to the stator and the rotor, respectively; and
a lead block holding a plurality of external connection terminals connected to the flexible printed circuit board, the lead block fixed to at least one of the rotor and the stator; wherein:
the flexible printed circuit board has a connection land to which the external connection terminals are connected,
the flexible printed circuit board has a main flexible printed circuit board housed within the annular space, and a sub flexible printed circuit board connected to the main flexible printed circuit board and the external connection terminals and extending at an angle relative to a longitudinal direction of the main flexible printed circuit board, and
the connection land is provided to the sub flexible printed circuit board.
1. A rotary connector comprising:
a stator;
a rotor rotatable relative to the stator;
a flexible printed circuit board housed within an annular space between the stator and the rotor and connected at both ends thereof to the stator and the rotor,
respectively; and
a lead block integrally holding a plurality of external connection terminals connected to the flexible printed circuit board, the lead block fixed to at least one of the rotor and the stator; wherein:
the flexible printed circuit board has a connection land to which the external connection terminals are connected via solder,
the flexible printed circuit board has a main flexible printed circuit board housed within the annular space, and a sub flexible printed circuit board connected to the main flexible printed circuit board and the external connection terminals and extending at an angle relative to a longitudinal direction of the main flexible printed circuit board, and
the connection land is provided to the sub flexible printed circuit board.
9. A rotary connector comprising:
a stator;
a rotor rotatable relative to the stator;
a flexible printed circuit board housed between the stator and the rotor and connected at both ends thereof to the stator and the rotor, respectively;
a lead block holding a plurality of external connection terminals connected to the flexible printed circuit board, the lead block fixed to at least one of the rotor and the stator; and
a holding member holding a region including the connection land of the flexible printed circuit board between the lead block and the holding member; wherein:
the flexible printed circuit board has a connection land to which the external connection terminals are connected via solder, and
in the holding member, a first holding portion positioning and fixing a portion, located within the annular space, of the flexible printed circuit board within the annular space, and a second holding member holding the region including the connection of the flexible printed circuit board between the lead block and the second holding member are disposed.
4. A rotary connector comprising:
a stator;
a rotor rotatable relative to the stator;
a flexible printed circuit board housed within an annular space between the stator and the rotor and connected at both ends thereof to the stator and the rotor,
respectively;
a lead block integrally holding a plurality of external connection terminals connected to the flexible printed circuit board, the lead block fixed to at least one of the rotor and the stator; and
a holding member holding a region including the connection land of the flexible printed circuit board between the lead block and the holding member; wherein:
the flexible printed circuit board has a connection land to which the external connection terminals are connected via solder, and
in the holding member, a first holding portion positioning and fixing a portion, located within the annular space, of the flexible printed circuit board within the annular space, and a second holding member holding the region including the connection land of the flexible printed circuit board between the lead block and the second holding member are disposed.
2. The rotary connector according to
3. The rotary connector according to
5. The rotary connector according to
a first holding portion positioning and fixing a portion, located within the annular space, of the flexible printed circuit board within the annular space, and a second holding member holding the region including the connection land of the flexible printed circuit board between the lead block and the second holding member are disposed.
6. The rotary connector according to
the stator has an outer cylinder,
the rotor has an inner cylinder facing the outer cylinder and is disposed so as to be coaxial with the stator, and
the flexible printed circuit board is housed within the annular space between the outer cylinder and the inner cylinder.
8. The rotary connector according to
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This application is a Continuation of International Application No. PCT/JP2017/006359 filed on Feb. 21, 2017, which claims benefit of priority to Japanese Patent Application No. 2016-108708 filed on May 31, 2016. The entire contents of each application noted above are hereby incorporated by reference in their entireties.
The present disclosure relates to a rotary connector disposed on a steering column of an automobile or the like.
On a steering column of an automobile, it is necessary to supply power for operating an air bag and transmit switching signals from a horn switch and various control switches, between a stator (stationary portion) and a rotor (rotary portion), and a rotary connector is used therefor.
In the rotary connector, the stator and the rotor are coaxially disposed so as to be rotatable, flat cables are housed and wound within a housing space defined between an outer cylinder forming the stator and an inner cylinder forming the rotor. The rotary connector is used as electrical connection means for an air bag inflator or the like mounted to a steering wheel having a limited number of revolutions such as a steering device of an automobile.
Japanese Unexamined Patent Application Publication No. 2013-219007 discloses a rotary connector in which a plurality of flat cables and a lead block are used for connecting rotor-side external connection terminals and stator-side external connection terminals.
However, the flat cables have problems, for example, (1) PET (polyethylene terephthalate) is used for an insulating film and thus the heat resistance thereof is low, (2) an increase in the number of signal lines also increases the number of flat cables since it is difficult to provide fine pitches, etc.
In addition, in the related art, the external connection terminals are connected to connection terminals of the flat cables by means of spot welding. Thus, for production of the rotary connector, a large-scale spot welding apparatus is required, and there is also a problem in that the assembling efficiency is poor since setting of the flat cables is performed on the spot welding apparatus.
A rotary connector includes: a stator; a rotor disposed so as to be relatively rotatable relative to the stator; a flexible printed circuit board housed within an annular space between the stator and the rotor and connected at both ends thereof to the stator and the rotor, respectively; and a lead block integrally holding a plurality of external connection terminals connected to the flexible printed circuit board, the lead block being fixed to at least one of the rotor and the stator, and the flexible printed circuit board has a connection land to which the external connection terminals are connected via solder.
According to this configuration, since the flexible printed circuit board including the connection land is used, and the lead block, which integrally holds the plurality of external connection terminals and is fixed to at least one of the rotor and the stator, is used, it is possible to stably connect the flexible printed circuit board to the external connection terminal even when the external connection terminals are connected via solder. Thus, in the production process, it is possible to connect the flexible printed circuit board to the external connection terminal, so that assembling is easy.
Hereinafter, a rotary connector according to an embodiment of the present invention will be described.
(Entire Configuration of Rotary Connector)
The rotary connector 1 is a connection device for transmitting electric signals between a steering column (not shown) and a steering shaft (not shown) of a vehicle.
As shown in
Within a main body of the rotary connector 1, an annular space (not shown) is formed between an inner cylinder portion 2A of the rotor 2 and an outer cylinder portion 3A of the stator 3 by combining the rotor 2 and the stator 3. Within the annular space, a first main flexible printed circuit board (hereinafter, referred to as first main FPC) 4 and a second main flexible printed circuit board (hereinafter, referred to as second main FPC) 5 for ensuring electric conduction between the rotor 2 and the stator 3 are preferably housed so as to be overlaid and wound in a spiral shape.
As shown in
As shown in
Openings 2B1 are preferably formed in the rotor-side connector portions 2B at positions facing the external connection terminals 7A. The external connection terminals 7A are connected to terminals of an external device for the rotary connector 1 via the openings 2B1.
As shown in
The external connection terminals 7A and the connection lands 17 of the first sub FPC 6 are connected to each other via solder. The solder is heated by a process such as reflow and then cooled to mechanically and electrically connect the external connection terminals 7A and the connection lands 17 of the first sub FPC 6 to each other.
As shown in
(First Main FPC and Second Main FPC)
As shown in
The first main FPC 4 is formed with a long length of about 50 cm, and both side edges thereof are formed straight so as to be parallel to and face each other. The first main FPC 4 is slidably housed within the annular space in a state of being wound in a spiral shape. As described above, since the first main FPC 4 is wound in a spiral shape and housed within the annular space, winding or unwinding of the first main FPC 4 are possible and an operation of turning a steering wheel (not shown) is permitted.
As shown in
As shown in
Similar to the first main FPC 4, the second main FPC 5 is also formed with a long length of about 50 cm, and both side edges thereof are formed straight so as to be parallel to and face each other. By winding the second main FPC 5 in a spiral shape and housing the second main FPC 5 within the annular space, winding or unwinding of the second main FPC 5 are possible and an operation of turning the steering wheel (not shown) is permitted.
As shown in
(First Sub FPC)
As shown in
As shown in
The first sub FPC 6 includes: the first wiring portion 6A to which the end portions 4A and 5A of the respective main FPCs 4 and 5 are attached; a second wiring portion 6B to which the rotor-side lead blocks 7 are attached; and a third wiring portion 6C connecting between the first wiring portion 6A and the second wiring portion 6B.
A plurality of connection terminals 16 that are connected to the connection terminals 10 and 11 provided in the end portions 4A and 5A of the respective main FPCs 4 and 5 are aligned on the first wiring portion 6A. A plurality of the connection lands 17 that are connected to the external connection terminals 7A of the rotor-side lead blocks 7 are preferably aligned on the second wiring portion 6B. A plurality of conductors (not shown) that connect between the connection terminals 16 and 17 of the respective wiring portions 6A and 6B are disposed on the third wiring portion 6C. The conductors of the third wiring portion 6C are interposed between and covered with a pair of the insulating films 14.
(First Holding Member)
As shown in
As shown in
The connection terminals 16 of the first wiring portion 6A and the connection terminals 10 and 11 of the end portions 4A and 5A of the respective main FPCs 4 and 5 are accurately connected to each other at predetermined positions as shown in
By the end portions 4A and 5A of the respective main FPCs 4 and 5 being held by the first holding portion 18A, the respective main FPCs 4 and 5 are housed within the annular space in a state where the main FPCs 4 and 5 stand in the width direction. Therefore, the respective main FPCs 4 and 5 are smoothly slidable within the annular space.
The first holding member 18 preferably includes a second holding portion 18B for holding the second wiring portion 6B of the first sub FPC 6. The rotor-side lead blocks 7 are placed on the second holding portion 18B, and the connection lands 17 of the second wiring portion 6B are interposed and held between the rotor-side lead blocks 7 and the second holding portion 18B. Accordingly, the connection lands 17 of the first sub FPC 6 shown in
The first holding member 18 includes a third holding portion 18C for holding the third wiring portion 6C of the first sub FPC 6.
As shown in
A plurality of positioning caulking pins 21 for positioning the first wiring portion 6A and the end portions 4A and 5A of the respective main FPCs 4 and 5 overlaid and attached to the first wiring portion 6A are provided on the first holding portion 18A of the first holding member 18 so as to project from a surface to which the first wiring portion 6A of the first sub FPC 6 is attached. As shown in
Next, a method for attaching the end portions 4A and 5A of the respective main FPCs 4 and 5, the first sub FPC 6, and the first holding member 18 will be described.
First, the rotor-side lead blocks 7 are connected to the connection lands 17 of the second wiring portion 6B of the first sub FPC 6 shown in
Next, the first wiring portion 6A is pressed against the first holding portion 18A while the positioning caulking pins 21, which are formed on the first holding portion 18A, are being inserted into the pin insertion holes 22, which are formed in the first wiring portion 6A of the first sub FPC 6 shown in
Next, the end portions 4A and 5A of the respective main FPCs 4 and 5 are placed on the first wiring portion 6A shown in
Next, the end portions 4A and 5A of the respective main FPCs 4 and 5 are pressed against the first wiring portion 6A while the positioning caulking pins 21 are being inserted into the pin insertion holes 22, which are formed in the end portions 4A and 5A of the respective main FPCs 4 and 5. At this time, the respective connection terminals 10 and 11 and the respective connection terminals 16 of the wiring portion 6A are overlaid on each other via solder.
Next, the distal ends of the positioning caulking pins 21 of the first holding member 18 shown in
Accordingly, the end portions 4A and 5A of the respective main FPCs 4 and 5 and the first wiring portion 6A are overlaid and are integrally positioned and held on the first holding portion 18A shown in
Next, preferably, the surfaces of the end portions 4A and 5A of the respective main FPCs 4 and 5 are pressed against the outer circumference of the inner cylinder portion 2C of the rotor 2 together with the rotor-side lead blocks 7 on the second holding portion 18B of the first holding member 18, and the respective hook portions 19 and 20 are engaged (coupled) with the attachment portions, which are provided to the rotor 2, by snap-in mechanisms. At this time, the rotor-side lead blocks 7 are inserted into the lead block insertion holes 2A1 of the rotor 2 and held in a state where the peripheries thereof are fitted. By attaching the first holding member 18 to the outer circumference of the inner cylinder portion 2C of the rotor 2 as described above, it is possible to attach the end portions 4A and 5A of the respective main FPCs 4 and 5 and the first sub FPC 6 at predetermined positions in the rotor 2.
As shown in
The stator-side lead blocks 9 are incorporated in stator-side connector portions 3B, which are provided on the outer circumference of the outer cylinder portion 3A of the stator 3 so as to project therefrom, via lead block insertion holes (not shown) formed in the outer cylinder portion 3A of the stator 3.
(Second Sub FPC)
As shown in
The second sub FPC 8 has heat resistance and is formed by aligning a plurality of conductors 26 formed from copper foils or the like on a sheet-shaped insulating film 25 that is formed from polyimide or the like and has transparency.
The second sub FPC 8 includes a third wiring portion 8C and a fourth wiring portion 8D on which the two stator-side lead blocks 9 are attached, respectively.
Connection lands (not shown) are formed on the third wiring portion 8C and the fourth wiring portion 8D, and the external connection terminals 9A of the stator-side lead blocks 9 are connected to the connection lands.
A plurality of connection terminals 27 are aligned on the first wiring portion 8A in the longitudinal direction of the main FPCs 4 and 5. A plurality of connection terminals 27 are also aligned on the second wiring portion 8B in the longitudinal direction of the main FPCs 4 and 5.
(Second Holding Member)
The rotary connector 1 includes the second holding member 28 for positioning and holding the other end portions 4B and 5B of the respective main FPCs 4 and 5 and the first wiring portion 8A and the second wiring portion 8B of the second sub FPC 8. The second holding member 28 is attached to the outer circumference of the outer cylinder portion 3A of the stator 3. The second holding member 28 is formed in a plate shape from a synthetic resin.
A plurality of positioning caulking pins 30 for positioning the respective wiring portions 8A and 8B of the second sub FPC 8 and the other end portions 4B and 5B of the respective main FPCs 4 and 5 attached on the wiring portions 8A and 8B are provided on the second holding member 28 so as to project from the surface on which the first wiring portion 8A and the second wiring portion 8B of the second sub FPC 8 are attached. Pin insertion holes 31 into which the positioning caulking pins 30 are inserted are formed in the respective wiring portions 8A and 8B of the second sub FPC 8 and the other end portions 4B and 5B of the respective main FPCs 4 and 5.
As described above, in the rotary connector 1, the first sub FPC 6 including the connection lands 17 and the second sub FPC 8 are used, and are, and the rotor-side lead blocks 7 and the stator-side lead blocks 9, which integrally hold the plurality of external connection terminals 7A and 9A and are fixed to the rotor 2 and the stator 3, respectively, are used. Accordingly, it is possible to stably connect the first sub FPC 6 and the second sub FPC 8 to the external connection terminals 7A and 9A by connecting the external connection terminals 7A and 9A via solder by a process such as reflow. Thus, in the production process, it is possible to connect the first sub FPC 6 and the second sub FPC 8 to the external connection terminals 7A and 9A by means of general soldering, so that assembling is easy. That is, it is not necessary to perform spot welding as in the related art.
In the rotary connector 1, the rotor-side lead blocks 7 and the stator-side lead blocks 9 are fixed and housed, the openings 2B1 and 3B1 are provided at the positions facing the external connection terminals 7A and 9A of these lead blocks, and the rotary connector 1 has the rotor-side connector portions 2B and the stator-side connector portions 3B, which are provided to the rotor 2 and the stator 3, respectively. Thus, it is possible to stably fix the rotor-side lead blocks 7 and the stator-side lead blocks 9 to the rotor 2 and the stator 3, respectively, in a manner where the rotor-side lead blocks 7 and the stator-side lead blocks 9 are connectable through the openings 2B1 and 3B1 from the outside of the rotary connector 1.
The rotary connector 1 has the first holding member 18, which holds the region including the connection lands 17 of the first sub FPC 6 between the rotor-side lead block 7 and the first holding member 18. Accordingly, even when the external connection terminals 7A and the first holding member 18 are connected to each other by solder, it is possible to stabilize the connection state between the connection lands 17 and the external connection terminals 7A.
In the rotary connector 1, preferably, the surfaces of the end portions 4A and 5A of the respective main FPCs 4 and 5 are pressed against the outer circumference of the inner cylinder portion 2C of the rotor 2 together with the rotor-side lead blocks 7 connected by solder to the connection lands 17 of the first sub FPC 6 on the second holding portion 18B of the first holding member 18, and the respective hook portions 19 and 20 are engaged (coupled) with the attachment portions, which are provided to the rotor 2, by snap-in mechanisms. By attaching the first holding member 18 to the outer circumference of the inner cylinder portion 2C of the rotor 2 as described above, it is possible to attach the end portions 4A and 5A of the respective main FPCs 4 and 5 and the first sub FPC 6 at predetermined positions in the rotor 2 by simple work.
As shown in
In the rotary connector 1, the first main FPC 4 and the second main FPC 5, which are housed within the annular space, and the first sub FPC 6, which extends in the direction orthogonal to the longitudinal direction of the main FPC, are provided. Accordingly, it is possible to increase the flexibility in design.
In the rotary connector 1, it is possible to attach the end portions 4A and 5A of the two main FPCs 4 and 5 to the single first sub FPC 6 and attach the other end portions 4B and 5B of the two main FPCs 4 and 5 to the single second sub FPC 8. Thus, it is possible to decrease the number of components, and it is possible to reduce the component cost.
In the connection work by the process of heating the main FPCs 4 and 5 and the respective sub FPCs 6 and 8 by a heater tool or the like, in the case of setting the main FPCs 4 and 5 and the respective sub FPCs 6 and 8 to a jig, it is possible to set the main FPCs 4 and 5 and the respective sub FPCs 6 and 8 to the jig at one time, and thus the assemblability is also good.
In the present embodiment, the example in which the two main FPCs 4 and 5 are used has been described. However, the present invention is applied to use of a single main FPC and is also applied to use of multiple main FPCs such as three or more main FPCs.
The present invention is not limited to the above-described embodiment. That is, a person skilled in the art may make various modifications, combinations, sub-combinations, and alterations for the components of the above-described embodiment within the technical scope of the present invention or the equivalents thereof.
The present invention is applicable to a rotary connector for transmitting electric signals between an annular stator and a rotor rotatably assembled to the annular stator.
Asakura, Toshiaki, Saito, Kengo
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